Advancing research in regeneration and repair of the motor circuitry: non-human primate models and imaging scales as the missing links for successfully translating injectable therapeutics to the clinic.

Magdalini Tsintou, Kyriakos Dalamagkas, Nikos Makris
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引用次数: 3

Abstract

Regeneration and repair is the ultimate goal of therapeutics in trauma of the central nervous system (CNS). Stroke and spinal cord injury (SCI) are two highly prevalent CNS disorders that remain incurable, despite numerous research studies and the clinical need for effective treatments. Neural engineering is a diverse biomedical field, that addresses these diseases using new approaches. Research in the field involves principally rodent models and biologically active, biodegradable hydrogels. Promising results have been reported in preclinical studies of CNS repair, demonstrating the great potential for the development of new treatments for the brain, spinal cord and peripheral nerve injury. Several obstacles stand in the way of clinical translation of neuroregeneration research. There seems to be a key gap in the translation of research from rodent models to human applications, namely non-human primate models, which constitute a critical bridging step. Applying injectable therapeutics and multimodal neuroimaging in stroke lesions using experimental rhesus monkey models is an avenue that a few research groups have begun to embark on. Understanding and assessing the changes that the injured brain or spinal cord undergoes after an intervention with biodegradable hydrogels in non-human primates seem to represent critical preclinical research steps. Existing innovative models in non-human primates allow us to evaluate the potential of neural engineering and injectable hydrogels. The results of these preliminary studies will pave the way for translating this research into much needed clinical therapeutic approaches. Cutting edge imaging technology using Connectome scanners represents a tremendous advancement, enabling the in vivo, detailed, high-resolution evaluation of these therapeutic interventions in experimental animals. Most importantly, they also allow quantifiable and clinically meaningful correlations with humans, increasing the translatability of these innovations to the bedside.

Abstract Image

Abstract Image

运动回路再生和修复的研究进展:非人类灵长类动物模型和成像尺度是成功将注射疗法转化为临床的缺失环节。
再生和修复是中枢神经系统损伤治疗的最终目标。中风和脊髓损伤(SCI)是两种非常普遍的中枢神经系统疾病,尽管有大量的研究和临床需要有效的治疗方法,但仍然无法治愈。神经工程是一个多样化的生物医学领域,它使用新的方法来解决这些疾病。该领域的研究主要涉及啮齿动物模型和生物活性、可生物降解的水凝胶。中枢神经系统修复的临床前研究已经取得了可喜的结果,显示了开发新的脑、脊髓和周围神经损伤治疗方法的巨大潜力。神经再生研究的临床转化过程中存在着一些障碍。在将研究从啮齿动物模型转化为人类应用的过程中,似乎存在一个关键的差距,即非人类灵长类动物模型,这是一个关键的桥梁步骤。利用实验恒河猴模型对中风病变进行注射治疗和多模式神经成像是一些研究小组已经开始着手的一条途径。理解和评估非人类灵长类动物在使用可生物降解水凝胶干预后受伤的大脑或脊髓所经历的变化似乎代表了关键的临床前研究步骤。现有的非人类灵长类动物创新模型使我们能够评估神经工程和可注射水凝胶的潜力。这些初步研究的结果将为将这项研究转化为急需的临床治疗方法铺平道路。使用连接体扫描仪的尖端成像技术代表了巨大的进步,能够在实验动物中对这些治疗干预进行体内,详细,高分辨率的评估。最重要的是,它们还允许与人类进行量化和临床有意义的关联,增加了这些创新到床边的可翻译性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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